Project description:The aim of this experiment was to investigate the regulation of gene expression by KLF3 and KLF8 in fetal erythroid cells by analyzing single and double mutant mouse models. Affymetrix microarrays were performed on RNA from TER119+ fetal liver cells from E13.5 wildtype, Klf8gt/gt, Klf3-/- and Klf3-/- Klf8gt/gt mice.

Project description:The aim of this experiment was to investigate the role of KLF3 in regulating gene expression at different stages throughout the erythroid maturation process. Affymetrix microarrays were performed on fetal liver cells (both TER119- progenitor cells and TER119+ erythroblast cells) from E14.5 wildtype and Klf3 KO mice. Four wildtype TER119- replicates, four Klf3 KO TER119- replicates, four wildtype TER119+ replicates, three Klf3 KO TER119+ replicates. All are from E14.5 fetal liver.

Project description:The aim of this study was to analyze the transcriptome of TER119+ fetal liver cells in the absence of the transcription factor KLF3 at murine embryonic day E14.5 Three wildtype (WT; Klf3+/+) and three knockout (KO; Klf3-/-) samples

Project description:Microarray analysis of wildtype, Klf8gt/gt, Klf3-/- and Klf3-/- Klf8gt/gt TER119+ E13.5 fetal liver cells

Project description:The aim of this experiment was to investigate the role of KLF3 in regulating gene expression at different stages throughout the erythroid maturation process. Affymetrix microarrays were performed on fetal liver cells (both TER119- progenitor cells and TER119+ erythroblast cells) from E14.5 wildtype and Klf3 KO mice.

Project description:The aim of this study was to analyze the transcriptome of TER119+ fetal liver cells in the absence of the transcription factor KLF3 at murine embryonic day E14.5

Project description:The aim of this experiment was to investigate the dysregulation of gene expression in whole E12.5 embryos containing a gene trap (CH) or point mutation (H275R) within the Klf3 gene Affymetrix microarrays were performed on RNA from wildtype, Klf3 H275R/H275R, Klf3 H275R/+, Klf3 CH homozygous and Klf3 CH heterozygous E12.5 embryos Four wildtype replicates, three Klf3 H275R/H275R replicates, four Klf3 H275R/+ replicates, four Klf3 CH homozygous replicates and two Klf3 CH heterozygous replicates of whole E12.5 embryos, litter-matched where possible.

Project description:Transcription cofactor Rcor1 has been linked biochemically both to neurogenesis and hematopoiesis. Here we studied the function of Rcor1 in vivo and showed it is essential to erythropoeisis during embryonic development. Rcor1 mutant proerythroblasts, unlike normal cells, can form myeloid colonies in vitro. To investigate the underlying molecular mechanisms for block of erythropoiesis and increased myeloid potential, we used RNA-seq to reveal the differentially expressed genes from erythroid progenitors due to depletion of Rcor1. RNA were extracted from FACS sorted CD71+,TER119- erythroid progenitors from control (Rcor1+/+ and Rcor1+/-) or Mutant (Rcor1-/- ) E13.5 fetal liver. Each library was made by pooling RNA from several fetal livers. Two biological replicates were made for either control or mutant condition.

Project description:The aim of this experiment was to investigate the dysregulation of gene expression in whole E12.5 embryos containing a gene trap (CH) or point mutation (H275R) within the Klf3 gene Affymetrix microarrays were performed on RNA from wildtype, Klf3 H275R/H275R, Klf3 H275R/+, Klf3 CH homozygous and Klf3 CH heterozygous E12.5 embryos

Project description:Using RNA-seq technology, we quantitatively determined the expression profile of microRNAs during mouse terminal erythroid differentiation. CFU-E erythroid progenitors were isolated from E14.5 fetal liver as the Ter119, B220, Mac-1, CD3 and Gr-1 negative, C-Kit positive and 20% high CD71 population. Mature Ter119+ erythroblasts were isolated from E14.5 fetal liver as C-Kit negative and Ter119 positive population. Consistent with nuclear condensation and global gene expression shut down during terminal erythroid differentiation, we found that the majority of microRNAs are downregulated in more mature Ter119+ erythroblasts compared with CFU-E erythroid progenitors. Examination of microRNA expression profiles in 2 cell types